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SBIR/STTR

High Specific Energy Lithium-ion Batteries with Novel Cathode, Phase I

Project Introduction

Energy Storage is a critical component of space-based platforms across the full spectrum of exploration, scientific experimentation, defense, communications and monitoring missions. NASA has set targets of 265 Wh/kg of 675 Wh/l for batteries for near-term energy storage applications. Li-ion battery technology has the highest energy density among rechargeable battery technologies. However, achieving the near-term goals require implementation of next-generation active materials. We propose to develop Li-ion cells that meet NASA's near term targets by combining our CAM-7 cathode material, the highest energy content market-ready cathode material available with market-ready Si-based anode materials. Because of its high reversible capacity (> 205 mAh/g), high discharge voltage (average 3.85 V vs. Li) and high density (4.8 g/cc), CAM-7 can yield higher energy Li-ion cells than any other market-ready cathode material. A version of CAM-7 targeting portable power and vehicle applications has been fully developed and, as part of its commercialization, is currently being transitioned to a 50 ton per year plant in Massachusetts. In the proposed Phase I program, TIAX will optimize the CAM-7 composition to yield the highest possible cell energy while still meeting the life targets, and simultaneously optimize an anode electrode incorporating a market-ready Si-based material. TIAX will then combine them in Li-ion cells that demonstrate the resulting system's ability to meet all NASA near-term energy, performance and life targets. The Phase I program will demonstrate, at the 200 mAh cell level, performance and cycling of electrode designs projected to meet and exceed NASA's near-term targets when they are incorporated in 18650 cells. A successful Phase I program will be followed by a Phase II program in which such 18650 cells are developed, assembled, and rigorously tested against NASA requirements.
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Anticipated Benefits

The absolute necessity of rechargeable energy storage for long-duration space missions, and the extremely high energy requirements and cost per unit mass of launching material into space make the premium for high specific energy and high energy density rechargeable batteries in space applications as high or higher than in any other sector. At the same time, the costs of space missions, and the extreme danger of manned space missions and necessity of energy storage for survival also create an extremely high premium for reliability of rechargeable batteries. Therefore, reliable, long life rechargeable batteries with the highest possible specific energy and energy density are a cross-cutting technology of very high value for a wide range of NASA applications (such as EVA suits, landers, rovers, habitats, vehicle power, electric aircraft and power for payloads), and therefore potential costs of development and small-volume manufacturing for the proposed battery technology are not likely to be critical hurdles to its commercial application in NASA platforms. As such, the proposed battery technology has potential for commercial application across the full spectrum of NASA's exploration, scientific experimentation, defense, communications and monitoring missions.
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